使用脑实质内电极检测受伤人类大脑中的扩散性去极化

Detection of spreading depolarization with intraparenchymal electrodes in the injured human brain.

作者信息

Jeffcote Toby, Hinzman Jason M, Jewell Sharon L, Learney Robert M, Pahl Clemens, Tolias Christos, Walsh Daniel C, Hocker Sara, Zakrzewska Agnieszka, Fabricius Martin E, Strong Anthony J, Hartings Jed A, Boutelle Martyn G

机构信息

Department of Neurosurgery, King's College Hospital, London, UK.

出版信息

Neurocrit Care. 2014 Feb;20(1):21-31. doi: 10.1007/s12028-013-9938-7.

DOI:10.1007/s12028-013-9938-7

PMID:24343564

Abstract

BACKGROUND

Spreading depolarization events following ischemic and traumatic brain injury are associated with poor patient outcome. Currently, monitoring these events is limited to patients in whom subdural electrodes can be placed at open craniotomy. This study examined whether these events can be detected using intra-cortical electrodes, opening the way for electrode insertion via burr hole.

METHODS

Animal work was carried out on adult Sprague-Dawley rats in a laboratory setting to investigate the feasibility of recording depolarization events. Subsequently, 8 human patients requiring craniotomy for traumatic brain injury or aneurysmal subarachnoid hemorrhage were monitored for depolarization events in an intensive care setting with concurrent strip (subdural) and depth (intra-parenchymal) electrode recordings.

RESULTS

(1) Depolarization events can be reliably detected from intra-cortically placed electrodes. (2) A reproducible slow potential change (SPC) waveform morphology was identified from intra-cortical electrodes on the depth array. (3) The depression of cortical activity known to follow depolarization events was identified consistently from both intra-cortical and sub-cortical electrodes on the depth array.

CONCLUSIONS

Intra-parenchymally sited electrodes can be used to consistently identify depolarization events in humans. This technique greatly extends the capability of monitoring for spreading depolarization events in injured patients, as electrodes can be sited without the need for craniotomy. The method provides a new investigative tool for the evaluation of the contribution of these events to secondary brain injury in human patients.

摘要

背景

缺血性和创伤性脑损伤后的去极化扩散事件与患者预后不良相关。目前，对这些事件的监测仅限于可在开颅手术时放置硬膜下电极的患者。本研究探讨了是否可使用皮质内电极检测这些事件，从而为通过钻孔插入电极开辟了道路。

方法

在实验室环境中对成年Sprague-Dawley大鼠进行动物实验，以研究记录去极化事件的可行性。随后，在重症监护环境中，对8例因创伤性脑损伤或动脉瘤性蛛网膜下腔出血而需要开颅手术的人类患者进行去极化事件监测，同时进行条带（硬膜下）和深度（脑实质内）电极记录。

结果

（1）可从皮质内放置的电极可靠地检测到去极化事件。（2）从深度阵列上的皮质内电极识别出可重复的慢电位变化（SPC）波形形态。（3）在深度阵列上，从皮质内和皮质下电极均一致地识别出已知在去极化事件后出现的皮质活动抑制。

结论

脑实质内放置的电极可用于在人类中持续识别去极化事件。该技术极大地扩展了对受伤患者去极化扩散事件的监测能力，因为电极放置无需开颅手术。该方法为评估这些事件对人类患者继发性脑损伤的作用提供了一种新的研究工具。

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使用脑实质内电极检测受伤人类大脑中的扩散性去极化

Detection of spreading depolarization with intraparenchymal electrodes in the injured human brain.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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